DE3716247A1 - OPTICAL MESSAGE TRANSMISSION SYSTEM WITH WAVELENGTH AND POLARIZATION MULTIPLEX - Google Patents

Abstract

A unidirectional and a bidirectional optical communication system is described in which a number of light signals are simultaneously transmitted via a transmission link consisting of an optical waveguide. The light signals have different wavelengths, signals with adjacent wavelengths exhibiting different directions of polarization. <IMAGE>

Description

The invention relates to a Message transmission system according to the preamble of Main claim. Such a transmission system is out EP-A-0 164 652 known.

In the known optical transmission system neighboring wavelengths a wavelength difference of 40 nm-60 nm. This wavelength difference is due to the Selectivity of the multiplexer / demultiplexer used given. Since the attenuation of the light signals in one Optical waveguide is strongly wavelength-dependent, and the Wavelength range is limited with low attenuation, can only be a few in the known system Light signals transmitted via an optical fiber.

The invention has for its object an optical Communication system to indicate that against the known at least twice the transmission capacity or an increased crosstalk attenuation between has adjacent optical channels.  

This problem is solved with the main claim mentioned means. Advantageous further developments are in contain the subclaims.

With the new transmission system, multiplexers and Demultiplexers with the same wavelength selectivity used as in the introduction Transmission system. It's just additional To provide polarization multiplexers and demultiplexers, so that the doubling of the transmission capacity with very little effort is possible.

The invention is described below using a Embodiment explained that in the single figure is shown schematically. Other versions are in included in the description.

The optical transmission system consists of two stations 4 and a transmission path 2 , which has an optical waveguide. One station contains a multiplexer 1 , the other a demultiplexer 3 . The multiplexer 1 is supplied with four light signals of different wavelengths, the direction of polarization of the first and third light signals being perpendicular to that of the second and fourth light signals. The light signals are combined by the multiplexer 1 to form a multiplex signal and fed via the optical waveguide to the demultiplexer 3 , which splits the multiplex signal back into the four original light signals.

The transmission link 2 consists of a polarization-maintaining optical waveguide or a non-polarization-maintaining optical waveguide and a polarization control device. A suitable polarization control device is known for example from DE-OS 31 50 697. The use of single-mode optical fibers is particularly advantageous in both cases.

When using discrete optical components for the multiplexer 1 and demultiplexer 3 , a polarization multiplexer or demultiplexer is connected in each station 4 to the transmission link 2 , to which one wavelength multiplexer or demultiplexer is connected in each polarization direction.

Due to the reversibility of the light propagation, the Polarization and wavelength multiplexers with the Demultiplexers be identical.

Examples are discrete polarization multiplexers

• - Beam splitter cubes made of quartz or flint glass
• - Foster beam splitter made of quartz or calcite
• - birefringent quartz prisms according to Wollaston, Rochon, S´narmont or Dove
• - Quartz glass body with translucent metal or Semiconductors (e.g. GaP, InP, Si or GaAs) - epitaxy - Interlayer according to Fresnel formulas or
• - Quartz glass plates according to different refractive indices Brewster law

suitable.

Examples are discrete wavelength division multiplexers dichroic interference filter (edge filter), Diffraction grating or wavelength selective Suitable for single-mode fiber couplers.  

In other embodiments of the transmission system, each station 4 contains a multiplexer and a demultiplexer or a Muldexer or a Bomudex (bidirectional optical multiplexer and demultiplexer), so that messages can be transmitted between the stations in both directions. A suitable Bomudex is known from DE-OS 35 05 636, a Muldex is cited there. In this case too, the transmission path 2 need only have one optical waveguide; however, there can also be one optical waveguide for each transmission direction.

The above-mentioned wavelength multiplexers with interference edge filters have a typical wavelength selectivity of 40 nm. Therefore, light signals of the same polarization direction must have a wavelength spacing of 40 nm predetermined by the wavelength demultiplexers, but light signals with adjacent wavelengths and different polarization directions only have a wavelength spacing of only 20 nm. This results, for example, in the following wavelengths l for the individual light signals:

l ₁ _{(| |)} = 1280 nm l ₂ _(⟂) = 1300 nm l ₃ _{(| |)} = 1320 nm l ₄ _(⟂) = 1340 nm

In preferred embodiments of the message transmission system, the multiplexer 1 and the demultiplexer 3 consist of polarization- and wavelength-selective PANDA fiber multi / demultiplexers, for example from Electronic Letters, Feb. 13, 86, Vol. 22, No. 4, p. 181 f are known, or from integrated optical components.

Instead of doubling the transmission capacity by using light signals with a wavelength spacing of 20 nm, an improvement in crosstalk attenuation can also be achieved by maintaining the wavelength spacing of 40 nm specified by the wavelength multiplexers and light signals of adjacent wavelengths nevertheless having different polarization directions. In such a system, the order of polarization and wavelength multiplex can be interchanged, ie the wavelength multiplexer is connected to the transmission link 2 and the polarization multiplexers are connected to it.

Claims (7)

1. System for unidirectional or bidirectional transmission of messages between at least two stations using light signals of different wavelengths, characterized in that light signals with adjacent wavelengths have different polarization directions and that each station contains a wavelength and polarization direction selective multiplexer and / or demultiplexer. 2. System according to claim 1, characterized in that the transmission path from at least one polarization-maintaining optical fiber. 3. System according to claim 1, characterized in that the transmission path from at least one Optical fiber and a polarization control device consists. 4. System according to claim 2 or 3, characterized in that the optical fiber is a single-mode optical fiber is.   5. System according to one of the preceding claims, characterized in that the multiplexer and / or the Demultiplexer from at least one fiber coupler, in particular from at least one wavelength and polarization-selective PANDA fiber couplers exist. 6. System according to any one of claims 1 to 4, characterized characterized in that the multiplexer and / or the Demultiplexer made of integrated optical components consist. 7. System according to any one of claims 1 to 4, characterized characterized in that the multiplexer and / or the Demultiplexer made of discrete optical components consist.